| Title |
THE ROLE OF CAPILLARY FORCES IN THE NATURAL STATE OF FRACTURED GEOTHERMAL RESERVOIRS |
| Authors |
N. Noel. A. Urmeneta, Shaun Fitzgerald, Roland. N. Horne |
| Year |
1998 |
| Conference |
Stanford Geothermal Workshop |
| Keywords |
capillary pressure, fractures |
| Abstract |
A lot of experiments into the natural state of geothermal reservoirs have been conducted using porous medium models, even though geothermal�systems are usually highly fractured. It is unclear whether a porous medium model is adequate in describing the natural state of a fractured�geothermal reservoir. Because of this, a dual porosity model is often invoked. The question of how heat and mass is transferred in fractures has�been widely investigated. The objective of this work was to further our understanding by investigating how heat and mass transfer is affected�by capillary forces. Also, the question of how capillary forces affect the stability of a water-saturated region overlying a liquid-dominated two-�phase zone was examined. The study was carried out by developing a two-dimensional numerical model representing a fractured geothermal�reservoir. The numerical simulations were carried to steady state with the use of a commercial simulator TETRAD (version 12). Results indicate�that due to capillary forces, the fractures act as heat pipes - transporting heat by the process of convection. The convection process was found to�be enhanced if there is no capillary pressure in the fractures. It was also determined that only if capillary forces are present can a system consist of�a water-saturated zone overlying a liquid-dominated two-phase zone remain stable.� |